TECH OFFERS

This technology is a patented synbiotics (combination of probiotics and prebiotics) cleaning solution that offers a safe and sustainable alternative to traditional cleaning products and disinfectants. When released onto the surface, the probiotics will digest and break down dirt, grime, and other unwanted substances while the prebiotics in the solution act as an additional source of nutrition for the probiotics. The resultant surface microbiome provides a continuous cleaning effect that is longer lasting than traditional cleaning chemicals and disinfectants. Often, the overuse of traditional chemicals and disinfectants results in antimicrobial resistance (AMR), allergenic reactions to the user, negative impact on the environment and short effective lifespan. With this synbiotics technology, users can overcome these limitations and achieve a long-term effective cleaning system and a natural microflora to the environment. When utilised in healthcare settings, the synbiotics cleaning solution demonstrated a higher reduction of pathogens (80% more), decreased AMR (up to 99.9%) and health-associated infections (52% lesser). The technology owner is interested in co-development projects and test-bedding opportunities with companies looking for a sustainable and long-lasting cleaning technology i.e., cleaning equipment and automation manufacturers/suppliers and cleaning service providers. This technology consists of proprietary dual action deep cleaning probiotics enzymes and specially formulated surfactants which helps to detox surfaces, break down biofilm and dirt components through a continuous cleaning effect and microscopically purifying down to the deepest pores of surfaces. Main features of this synbiotics cleaning technology include: High efficacy and able to target broad spectrum of pathogens Long-lasting and continual cleaning efficacy Safe and non-toxic Decreased AMR (up to 99.9%) Reduction in health-associated infections (52%) Suitable for water-resistant surfaces This technology can be deployed across several sectors including healthcare, commercial, industrial, and residential buildings on water resistant surfaces (floor and walls). The technology owner has successfully test-bedded the technology in local healthcare institutions. By varying the probiotics used, this technology may also be used in agriculture, aquaculture, animal husbandry and personal care applications to extend the benefits of probiotics into new products. The global healthcare facilities and household cleaner market is estimated to be valued at US$55 billion in 2022. With the continuous use of chemical disinfectants, multi-resistant bacteria like super bugs and MRSA are expected to raise AMR and account for a rise in AMR-related deaths. This synbiotics cleaning technology can overcome and reduce AMR concerns, maintaining a long-term effective cleaning system and a natural microflora to the environment. This technology overcomes limitations in using conventional cleaning products and disinfectants such as: Limited effective short lifespan results Increasing health risks (acute & chronic) to both the user and consumers Requires more manpower & cleaning frequency Difficultly in breaking down biofilms, causing recurring odour and dirt It also provides and maintains a chemical-free, long-term effective cleaning system through the dual action deep cleaning efficiency. The technology owner is interested in co-development projects and test-bedding opportunities with companies looking for a sustainable and long-lasting cleaning technology i.e., cleaning equipment and automation manufacturers/suppliers and cleaning service providers. probiotics, prebiotics, cleaning, synbiotics, sustainable, eco-friendly, long-lasting, microbiome, antimicrobial, antimicrobial resistance, natural, health associated infections, sanitisation, disinfectant, chemicals Environment, Clean Air & Water, Biological & Chemical Treatment, Sanitisation, Chemicals, Bio-based, Sustainability, Sustainable Living

Biodegradable adhesives are a class of adhesives derived from natural materials such as as plant-based polymers or proteins, and they do not contain any synthetic plastics or other harmful chemicals. They are more environmentally friendly, as they do not release harmful pollutants into the environment when they break down. They are also often compostable, which means that they can be disposed of in a way that is beneficial to the environment. This technology is a patented environmentally friendly, biodegradable adhesive that overcomes the limitations of fossil-fuel based adhesives. Made from a natural polymer and other natural materials, this bio-adhesive can exhibit 100% biodegradability within 30 days, does not contaminate the environment and can be separated by water. The adhesive can be applied onto a variety of substrates including paper, leather, foams, and wood to name a few. The technology owner is interested in joint R&D projects with companies who require a biodegradable and sustainable adhesive solution. This biodegradable adhesive technology is based on 100% natural polymers and ingredients. Some features of the adhesive are as follows: Exhibits biodegradation in 30 days (99% decomposition rate) Comprises of 90% bio-based carbon content Can be easily separated from the substrate by water Non-toxic and safe for the environment Good operating temperature range (-4°C to 80°C) The adhesive technology is certified by DIN-CERTCO and received 'non-toxic' results in a plant ecological toxicity test. In addition, the fresh bio-ratio of plant compost is higher than the healthy production of plant seeds and seedlings. Potential applications of this biodegradable adhesive include (but not limited to): Packaging Construction Interior furniture Commercial products  This technology has been validated on various substrates including wood, paper pulp, styrofoam, cotton, leather, and ceramics. Non-toxic and made from 100% natural materials Does not release harmful pollutants when broken down – adhesive has been certified to show no negative impact on the environment ecosystem (soil, fish, water fleas, algae) Uses water to separate from the substrate The technology owner is interested in joint R&D projects with companies who require a biodegradable and sustainable adhesive solution. adhesive, biodegradable, environmentally friendly, eco-friendly, water-soluble, natural, polymer, bio-based Materials, Plastics & Elastomers, Chemicals, Polymers, Bio-based, Sustainability, Circular Economy

Industrial robots are typically deployed indoors in factories for industrial automation applications such as manufacturing and production. Outdoor deployment in the absence of the traditional work cell boundaries, will typically necessitate safety precautions and perimeter fencing in order to maintain a safe working perimeter between the robot and any surrounding personnel. A Singapore-based research team has developed an integrated Outdoor Mobile Robotic Platform (OMRP) capable of executing the manual operations of human workers outdoors. The solution is based around the concept of a weather-resistant industrial robot arm mounted on a mobile vehicle platform. The system is integrated with vision systems and sensors to provide the appropriate safety zone monitoring and offers versatility catering to various use-cases via custom end effectors. The system primarily comprises the use of a 6-axis industrial robot arm at the rear end of a truck. The effective reach of the robot is further enhanced through a customised linear track to extended to either ends of the vehicle. Depending on the application, an operator may be on deck to control, facilitate, and provide a watchful eye on the operations. A combination of vision cameras, laser sensors, and other sensor systems provide the necessary safety zone monitoring and perimeter fencing, while a linear track extends the robot’s reach and dexterity to cover a multitude of functions. The OMRP system translates the strengths of the industrial robot arm from the factory floor to the outdoor environment, by utilising the robot arm to execute labour intensive manual operations at higher efficiency and precision. The solution is well suited to serve as an Automated Lane Closure and Re-Opening System (ALCROS) via the deployment and eventual retrieval of traffic signages and cones. By customising the end effector and/or incorporating a tool changer, the same system may also be applied to a multitude of use cases, including and not limited to: Automated placement and retrieval of road closure equipment Paint removal and washing of roadside parapet and kerbs Road marking painting/removal On top of improving safety, the required manpower required for the operation may be reduced to as high as 80% compared to current manual processes. The value proposition offered by the ALCROS system is being the first known automation solution to simultaneously accomplish the following tasks: Deployment and retrieval of traffic cones while in the forward driving mode Deployment and retrieval of traffic signages while in the forward driving mode While there are commercial solutions that are able to place and retrieve cones in a straight line, there has been no demonstration of the ability to deploy and retrieve them in a tapered pattern. It is noted that most of the commercial solutions execute cone collection in reverse, which if practised in Singapore would be a violation of expressway regulations. Additionally, solutions for warning signs placement and retrieval are not readily available yet. The novelty of ALCROS lies in its ability to accomplish all the above task requirements within a single vehicle setup, while complying with traffic regulations in the Singapore context, which no known commercial solution has so far satisfied. Through this new workflow, ALCROS is able to improve on productivity by reducing the number of personnel required, and more importantly, enhance their safety. Robotics, Mobile platform, Outdoor Manufacturing, Assembly, Automation & Robotics, Logistics, Transportation, Waste Management & Recycling, Automation & Productivity Enhancement Systems

Maskless laser lithography (MLL) is a microfabrication technique used to create complex patterns on a substrate with high precision and resolution.  A Singapore-based research team has developed a compact and cost-effective MLL system by seamlessly integrating hardware and software components. By seamlessly integrating with computer-aided design software, operators can easily input arbitrary patterns for exposure. The small system footprint makes it ideal for research labs and offers widespread applicability across various fields, including microfluidics, electronics, and nano/micro mechanical systems. The system's cost-effectiveness extends its benefits beyond university research labs, presenting opportunities for semiconductor and medical companies to leverage its capabilities. This technology is available for IP licensing or further co-development in view of scale-up manufacture and commercialisation. Max exposable area 150mm x 150mm Max substrate size 150mm x 150mm Resolution 0.8 microns Precise cartesian movement, laser focus and pattern alignment using camera vision Galvo mirror-based laser steering Feedback-enabled actuators, optical elements, and electronic control systems Proprietary software efficiently processes computer-aided drawings of nano/microstructures Smart focusing mechanism, image recognition (pattern stitching) This technology offers a versatile nano/micro lithography tool for research labs creating sub-micron sized features and to facilitate rapid prototyping of circuits and devices. The cost-effective desk-top configuration provides researchers and industry practitioners access to lithography techniques without the need for complex infrastructure and facilities. Applications extend to the design and fabrication of micro-electro-mechanical systems (MEMs), biomedical devices and microelectronics, such as in the following sectors: Medical (including microfluidics) Semiconductor Microelectronics Biotechnology and life sciences Advanced materials research The global Maskless Lithography System market size is estimated to be worth US$ 336.06 million in 2022 and forecasted to increase to US$ 501.43 million by 2028 with a CAGR of 6.90%.The lithography market is also projected to experience sustained growth in the coming decades due to the increasing demand for 5G, AIoT, IoT, and semiconductor circuit performance and energy consumption optimization. Similar laser lithography systems use complex, expensive, and sensitive components such as employing the use of a fast-moving optical head while this technology directly steers the laser beam to expose the patterns. Arbitrary pattern lithography systems such as electron beams lithography (EBL) typically require large vacuum chambers, pumps, chillers, and precise electronics for steering electron beams. Fast UV mask aligners require masks that fixed chrome patterns on quartz or glass plates. Compared to current state-of-the-art systems, this technology offers competitive performance at reduced cost, complexity and with a substantially smaller footprint.   Materials, Semiconductors, Electronics, Lasers, Optics & Photonics, Healthcare, Medical Devices

The regulations aimed at reducing carbon emissions have led to the adoption of a remodelling strategy that focuses on decreasing the energy usage of buildings. This can be achieved through measures such as thermal insulation and retrofitting, which extend the lifespan of buildings while reducing their energy consumption. The proposed technology by a Singapore-based research team utilises proprietary Fibre Reinforced Polymer (FRP) material for reinforcement to enhance the longevity of buildings. It contains a modified epoxy adhesive used in the FRP-adhesive-concrete interfaces to provide a range of advantageous properties, that include being 5 times lighter while 10 times higher tensile and flexural strength than steel, cost-effective in production, easily shaped, demonstrating high corrosion resistance, and offering both flexibility and tolerance to misalignment. In addition, through the modification of bonding agents and surface aerogel insulation, the fire retardancy of the material had been enhanced by 3 classes to V-0 rating according to the UL 94 plastic flammability standard. Among the superinsulation materials, aerogel stands out with its unique acoustic properties and significantly lower thermal conductivity of approximately 0.014 W/m.K. Additionally, it possesses exceptional physical and chemical attributes, such as its translucent structure. As a result, it is widely regarded as one of the most highly promising materials for thermal insulation in building applications. The FRP technology is currently pending fire testing to meet local regulatory requirements (e.g., BS 476 Part 20-23) and will be subjected to evaluation by the Building Innovation Panel of BCA in coming months. The technology owner is keen to support interested industrial partners to fabricate larger prototype of the FRP for test-bedding on site, and eventually license the intellectual property to the industrial partner for commercialisation. Through the external strengthening of structural components, the fire retardant FRP improves structural properties, leading to reduced environmental concerns, lower construction material costs, decreased labour requirements, and reduced CO2 emissions into the atmosphere. Silica aerogels typically exhibit a longitudinal acoustic velocity on the order of 100 m/s, making them suitable for various applications in acoustic devices for noise insulation. Furthermore, aerogels boast the lowest refractive index and dielectric constant among all solid materials. FRP is regarded as superior to conventional steel due to its notable advantages, including exceptional corrosion resistance, high flexibility, and tolerance to misalignment. It is also lightweight, cost-effective to produce, easy to shape, and possesses high tensile and flexural strength. Furthermore, FRP exhibits elastic properties. By modifying the bonding agent used in FRP-adhesive-concrete interfaces, the strength from the FRP developed using the proposed technology can be enhanced by 12%, and its flammability can be improved from an unclassified level to achieving a V-0 rating under the standard UL-94. Previously, aerogel found limited use in small-scale applications within the aerospace industry. However, there is now a growing trend of employing aerogel for larger building-integrated applications, aiming to reduce energy consumption. This has sparked renewed interest from both start-ups and established insulation manufacturers. The technology itself is relatively straightforward, making it an attractive choice for building owners and architects seeking a simple solution to lower energy costs. By incorporating aerogel insulation, buildings can enhance their energy performance and provide improved comfort and satisfaction for occupants. Remarkably, this technology can be applied to various types of buildings, including HDB flats, shop houses, commercial and industrial buildings, as well as both landed and non-landed housing units. Moreover, its versatility extends to both existing structures and new construction projects. Looking ahead, aerogel insulation is poised to play a significant role in the future of green building materials. Its applications extend beyond buildings and encompass areas such as architecture, vehicles, aircraft, spacecraft, and marine insulation. Meanwhile, fire retardant fibre reinforced polymer (FRP) materials have emerged as a valuable solution for building retrofitting and structural strengthening applications, particularly in terms of fire safety. These materials combine the strength and flexibility of FRP with fire-resistant properties, making them an effective choice for enhancing the fire resistance of existing structures or strengthening them to withstand fire-related incidents. When applied to building retrofitting, fire retardant FRP materials can be used to upgrade the fire performance of structural elements such as columns, beams, slabs, and walls. This approach is particularly beneficial for structures that do not meet current fire safety codes or have aged fire protection systems. The unique value proposition of aerogel insulation materials lies in their exceptional thermal performance, lightweight nature, versatility, moisture management capabilities, enhanced comfort, longevity, and environmental sustainability. These qualities make aerogel insulation materials an attractive choice for a wide range of building applications, offering significant energy savings and improved building performance. The fire retardant FRP is able to enhance fire resistance, provide structural strengthening, resist corrosion, offer lightweight and space-efficient solutions, ensure flexibility and ease of installation, offer cost-effectiveness, and provide design versatility. These qualities make fire retardant FRP materials a compelling choice for improving the fire safety and structural integrity of buildings. Aerogel blanket, Thermal insulation, Acoustic insulation, Fibre reinforced polymer, Fire retardant Materials, Composites, Environment, Clean Air & Water, Biological & Chemical Treatment, Green Building, Façade & Envelope

Lithium-ion battery technology using graphite anode material is widely used in consumer electronics, electric vehicles and energy storage systems. However, for high-power, ultra-fast charge/discharge applications, e.g., regenerative braking in cars, electric buses, batteries for aircraft/marine sectors, graphite anode material is less preferred due to safety and performance limitations. Currently, lithium titanate oxide or LTO battery technology is one of the commercially available solutions for high power applications. LTO battery is a type of rechargeable battery that has a longer cycle life, faster charging and safer than conventional lithium-ion batteries. Despite these advantages, LTO battery is up to two times more costly than conventional lithium-ion batteries in the market, and has considerably lower specific energy density of about 60-110 Wh/kg than conventional lithium-ion chemistries, e.g., 90-165 Wh/kg for LFP and 150-270 Wh/kg for NMC.   The technology proposed by the Singapore-based research team relates to a method to synthesise a proprietary formulation of lithium-ion battery anode consists of mesoporous titanium dioxide (TiO2) material. This novel anode formulation for high power batteries is potentially able to reduce the production cost to about US$250-300 per kWh from US$500-600 per kWh for LTO, according to preliminary estimates by the team based on manufacturing capabilities in China. The cost reduction is derived from the use of cheaper TiO2 raw materials (vs. LTO) and the simple manufacturing process. The mesoporous TiO2 anode material can be integrated into existing manufacturing lines for lithium-ion cells without the need for new equipment. Using 18650 cylindrical cell of mesoporous TiO2 anode material with manganese-based cathode material, the cell achieved superior charging rate performance of up to 5C, energy density level of 70-100 Wh/kg and a cycle life of about 10,000 cycles, while retaining 75% of the initial capacity. The research team anticipated that the TiO2 cells will have up to 30% better energy density than LTO cell technology. The research team is seeking industry partners to collaborate for a 5-10 kWh test bed project on a fast-charging application including uninterrupted power supply (UPS), regenerative braking and etc. The research team is able to tap on their in-house facilities to fabricate mesoporous TiO2 cells (32700 or 18650 format) using the novel anode formulation.   Energy density: 70-100Wh/kg Charging: 3-4C in 15-20min Rapid pulse charging: 10-20C in 3-6min Discharging: 5-10C in 6-12 min Long cycle life: 5000-10000 cycles No metal plating, no micro-shorting and no thermal runaway Lower cost than current high-power battery solutions in the market: estimated $250-300/kWh Relatively lesser supply chain issue hence easy to scale for market penetration Regenerative braking in cars, electric buses, aerospace and marine sectors Uninterrupted power supply systems in data centres or solar energy storage systems to address intermittency issues Depending on the type of applications considered, the market is segmented to different sectors including electric powertrain, aerospace/marine industries and energy storage systems. The global market for LTO batteries is expected to grow at a CAGR of 17.92% from 2022 to 2030. The growth of the market is driven by the increasing demand for LTO batteries in the aforementioned applications. Unlike the high-power battery solutions offered in the market, the proposed high-power battery technology solution is safe and inexpensive with moderate energy density, enabled by the mesoporous TiO2 anode material formulation. The team expected that the anode material formulation has relatively lesser supply chain issue thanks to abundance of its raw material, hence it is easy to scale up the technology for market penetration. Energy, Battery & SuperCapacitor, Manufacturing, Chemical Processes

The term nature-positive describe a world where nature, species, and ecosystems are being restored and is regenerating rather than declining, which leads to an increased biodiversity, improved ecosystem services and reduced climate change impacts. The realisation of a nature-positive world has been hindered by economic, political, social and technological factors, as well as a lack of research on the impact of economic activities on natural capital and society at large. One of the widely used approach to enable a nature-positive society is the quantification and evaluation of Scope 3 emissions and life cycle assessment (LCA) of natural capital or resources. Scope 3 emissions are indirect emissions that occur in the value chain of an organisation including emissions from the transportation of goods, the use of sold products, and the disposable of waste. Life cycle assessment is a methodology for evaluating the environmental impacts of a product or service throughout its entire life cycle. This includes the extraction of raw materials, the production process, the transportation, the use, and the disposal of the product or service. LCA can be used to identify opportunities to reduce the environmental impacts of a product or service. A startup team based in Japan has developed a comprehensive assessment framework to enable environmental, social and governance (ESG) evaluation of products and services, tracing back through its supply chain. The assessment framework uses a combination of the inclusive wealth index (a metric for measuring the total wealth of a country, including natural, human, social, and produced capital) and environmental and social LCA to assign quantitative values to natural resources. The quantitative values were obtained from years of in-house research and product or services cost component data gathered by the team, providing ESG assessment and scoring of close to 16,000 products and services based on about 3,290 indicators of ESG ranging from human rights, wages, child labour, gender equality, greenhouse gas emissions to consumption of natural resources before the products are supplied in different geographies. The assessment framework is developed as a software tool for the user to visualise a product’s supply chain map. It could trace back not only direct suppliers but also secondary, tertiary and upstream suppliers to identify hot spots or high-risk areas for ESG indicators, allowing the user to prioritise and plan for the remediation actions. In addition, users may benchmark their level of achievement in ESG indicators with the industry average, identify their company's strengths and areas of improvements. The startup team is seeking to partner corporations and municipalities that requires supply chain ESG assessment and natural capital evaluation. The startup team is also opened to explore co-development collaborations, e.g., to customise the platform for different industries. The software tool provides the assessment framework that enables quantitative evaluation of the economic value of natural capital in terms of flows and stocks. Provides illustration showing the supply chain impact of close to 16,000 products and services based on about 3,290 ESG indicators, e.g., GHG emissions for Scopes 1 to 3 per TCFD, CDP, GHG Protocol guidelines. This helps to support companies in their ESG awareness, investor relations and prioritisation of remediation activities. Provides dashboard and benchmarking for the level of ESG impact relative to industry averages. Validity and reliability of the ESG assessment is verified and certified by a third-party international academic organisation, i.e., The Organisation for Sustainametrics with reference to ISO 14020:2000, ISO 14001:2015, ISO 14075 and SA8000 standards. The supply chain ESG analysis could be applied in various sectors including real estates and logistics that are becoming essential in major global markets. Quantitative evaluation of the economic value of natural capital in both flows and stocks could be applied in not just corporations but for countries and municipalities. Developing an impact assessment method that covers the impacts of nature, people, and man-made resources by extending the scope of LCA assessment, extending the inclusive wealth index used by national and local governments to corporate organizations, and enabling a plan-do-check-act (PDCA) cycle based on cross-referencing. Social impact, Natural capital, Supply chain, Sustainability assessment Infocomm, Big Data, Data Analytics, Data Mining & Data Visualisation

As the world continues to make strides in artificial intelligence (AI), the need for transparency in the field intensifies. Clear and understandable explanations for the predictions of AI models not only enhances user confidence but also enables effective decision-making. Such explanations are especially crucial in sectors like healthcare where predictions can have significant and sometimes life-changing consequences. A prime example is the diagnosis of cardiovascular diseases based on heart murmurs, where an incorrect or misunderstood diagnosis can have severe implications. The technology, DiagramNet, is designed to offer human-like intuitive explanations for diagnosing cardiovascular diseases from heart sounds. It leverages the human  reasoning processes of abduction and deduction to generate hypotheses of what diseases could have caused the specific heart sound, and to evaluate the hypotheses based on rules. The technology tests which murmur shapes are present in the heart sound to determine the underlying cardiac disease. This approach of abductive-deductive AI reasoning can also be applied to other diagnostic or detective tasks. DiagramNet uses deep learning AI to perform four key steps: ‘Observe event’ by observing displacement to interpret its amplitude, murmur location, and the heart phase in which the murmur occurred. ‘Generate plausible explanations’ by listing possible diagnoses, retrieving respective murmur shape functions, and initialising their corresponding shape hypotheses. ‘Evaluate plausibility’ by fitting each hypothesis to the observation, evaluating the rules in terms of shape goodness-of-fit in conjunction with matching the murmur heart phase. ‘Resolve explanation’ with the hypothesis-fitted inference and the initial inference to make a final inferred diagnosis. By offering clinically relevant explanations in an accessible format, DiagramNet bridges the gap between complex AI predictions and user understanding, fostering trust and actionable insights in critical healthcare applications. Many existing AI models struggle to provide meaningful and easily interpretable explanations—they are either too technical or too simplistic. As such, there is an opportunity for a novel AI model that can generate thorough and easily understandable explanations. In the medical field, diagrams can be particularly beneficial when it comes to illustrating complex observations and making interpretations more accessible to non-technical users and patients alike. Enhances interpretation of AI decisions through a design framework for diagrammatic reasoning. Accelerates and strengthens the adoption of AI technology by leveraging diagrams that adhere to domain conventions. Presents a diverse array of explanation types, namely, abductive, contrastive and case-based explanations. Facilitates trust and consistency in AI-based cardiac diagnosis by providing murmur diagrams which are a universally understood tool among clinicians. Explainable Artificial Intelligence, Healthcare ICT Infocomm, Artificial Intelligence

Timely and adequate rehabilitation is critical in facilitating post-stroke recovery. However, the organisation and delivery of rehabilitation are resource-demanding, and are only available in ~25% of stroke survivors in low-middle-income countries. Therefore, innovative solutions are urgently required to improve access to stroke rehabilitation services. Our team developed a platform to assist remote dissemination of physio- and occupational therapy services. Our platform enables post-stroke rehabilitation services to be delivered using consumer-grade devices (e.g., smartphones and tablet devices) and artificial intelligence technology, thereby breaking many physical and resource barriers to rehabilitation service access. Our platform is designed for hospitals, rehabilitation centres and post-stroke service providers. The system consists of two interfaces – the therapist portal and patient application. Portal system enables remote prescription of exercises and monitor exercise performance and progress, whereas the patient application acts as a “smart therapist” in providing real-time instructions and feedback. The system addresses limitations faced by the conventional phone interview- and video conference style of telemedicine, which mainly relies on self-reporting and subjective recall. Using devices’ built-in camera and relevant Internet of Things (IoTs), we automated the evaluation process using algorithms with key features identified by professional therapists for providing “supervision” through real-time feedback. The core technology utilizes artificial intelligence and computer vision. The bodily information is evaluated against experts’ criteria for providing real-time feedback to facilitate automated and “supervised” telerehabilitation. Features: Easy to setup and use, enable user to undergo rehabilitation with no time and place restriction Real-time feedback Validated objective measurements and evaluation Can be run on consumer-grade smartphones/tablets, no extra device required The system is suitable for use and applicataion in healthcare and residential care industry. Further rehabilitation-relevant services are under development to cater a wider spectrum of neurological conditions, including speech and cognition. Market – Elderly Health Centres, Elderly / Nursing Homes, Government, Social Welfare Departments or organizations, Individual for home use Distribution -- Worldwide, particularly in low-to-middle income countries where physical and functional (e.g., difficulty ambulating from home to centre), social (e.g., inconvenience of patient and/or caregiver), and financial barriers (e.g., costs, opportunity costs during working hours, and duration) are evident. Features: Easy to setup and use Close the gap in healthcare service using accessible and affordable technology Validated objective measurements and evaluation Customizable exercises and real-time feedback system Low hardware requirement, runs on consumer-grade smartphones/tablets, no extra device required The current “State-of-the-Art” of remote- and telerehabilitation adopted worldwide during the COVID-19 pandemic relies largely on the use of phone interviews and video conferences, which face limitations including labor-intense, subjective, and prone to recall bias. Our technology holds its UVP by addressing these limitations through automated and objective measurements via artificial intelligence and information captured using embedded cameras and other Internet of Things. It enables minimal human resources for monitoring and managing safe home-based rehabilitation. Infocomm, Artificial Intelligence